Severe performance drop and fire risk due to the uneven lithium(Li) dendrite formation and growth during charge/discharge process has been considered as the major obstacle to the practical application of Li metal batt...Severe performance drop and fire risk due to the uneven lithium(Li) dendrite formation and growth during charge/discharge process has been considered as the major obstacle to the practical application of Li metal batteries.So inhibiting dendrite growth and producing a stable and robust solid electrolyte interface(SEI) layer are essential to enable the use of Li metal anodes.In this work,a functional lithiophilic polymer composed of chitosan(CTS),polyethylene oxide(PEO),and poly(triethylene glycol dimethacrylate)(PTEGDMA),was homogeneously deposited on a commercial Celgard separator by combining electrospraying and polymer photopolymerization techniques.The lithiophilic environment offered by the CTS-PEO-PTEGDMA layer enables uniform Li deposition and facilitates the formation of a robust homogeneous SEI layer,thus prevent the formation and growth of Li dendrites.As a result,both Li/Li symmetric cells and LiFePO4/Li full cells deliver significantly enhanced electrochemical performance and cycle life.Even after 1000 cycles,the specific capacity of the modified full cell could be maintained at65.8 mAh g^(-1), twice which of the unmodified cell(32.8 mAh g^(-1)).The long-term cycling stability in Li/Li symmetric cells,dendrite-free anodes in SEM images and XPS analysis suggest that the pulverization of the Li anode was effectively suppressed by the lithiophilic polymer layer.展开更多
Metal hydride-nickel cell is one of the best choices for hybrid electric vehicle for its high specific energy density,security,reliability and renewability.However,its poor capability under high temperature and low sp...Metal hydride-nickel cell is one of the best choices for hybrid electric vehicle for its high specific energy density,security,reliability and renewability.However,its poor capability under high temperature and low specific power restrict its applications.Our studies on the metal hydride-nickel cell with different loading densities show that Ni(OH) 2 with CoOOH has good oxidation and reduction properties and proton spread rate when the loading density is 0.617 kg/m2.The power density and energy density can be as high as 1 250 W/kg and 49.4 W·h/kg respectively when Ni(OH) 2 with CoOOH was used in high power battery with the nickel foam.展开更多
In MH/Ni high power battery production, a large percent of batteries were found with an open circuit voltage lower than 1.18 V after formation, open circuit voltage of another large percent of batteries could be even ...In MH/Ni high power battery production, a large percent of batteries were found with an open circuit voltage lower than 1.18 V after formation, open circuit voltage of another large percent of batteries could be even as low as1.00 ~ 1.10 V after one month sitting.In this situation, we analysed the causes of the problem, and provided some efficient solution based on many experiments.It was proved that these solutions are working very well to prevent the low open circuit voltage and being used in real production.展开更多
基金supported by the Natural Science Foundation of Jiangsu Province (BK20170237)National Natural Science Foundation of China (21808094 and 51871113)+1 种基金Key Research and Development Program of Xuzhou (KC17004)Startup Funding for Introduced Talents of Jiangsu Normal University (16XLR015)。
文摘Severe performance drop and fire risk due to the uneven lithium(Li) dendrite formation and growth during charge/discharge process has been considered as the major obstacle to the practical application of Li metal batteries.So inhibiting dendrite growth and producing a stable and robust solid electrolyte interface(SEI) layer are essential to enable the use of Li metal anodes.In this work,a functional lithiophilic polymer composed of chitosan(CTS),polyethylene oxide(PEO),and poly(triethylene glycol dimethacrylate)(PTEGDMA),was homogeneously deposited on a commercial Celgard separator by combining electrospraying and polymer photopolymerization techniques.The lithiophilic environment offered by the CTS-PEO-PTEGDMA layer enables uniform Li deposition and facilitates the formation of a robust homogeneous SEI layer,thus prevent the formation and growth of Li dendrites.As a result,both Li/Li symmetric cells and LiFePO4/Li full cells deliver significantly enhanced electrochemical performance and cycle life.Even after 1000 cycles,the specific capacity of the modified full cell could be maintained at65.8 mAh g^(-1), twice which of the unmodified cell(32.8 mAh g^(-1)).The long-term cycling stability in Li/Li symmetric cells,dendrite-free anodes in SEM images and XPS analysis suggest that the pulverization of the Li anode was effectively suppressed by the lithiophilic polymer layer.
基金Sponsored by the National High Technology Research and Development Program of China(2007AA11A104)
文摘Metal hydride-nickel cell is one of the best choices for hybrid electric vehicle for its high specific energy density,security,reliability and renewability.However,its poor capability under high temperature and low specific power restrict its applications.Our studies on the metal hydride-nickel cell with different loading densities show that Ni(OH) 2 with CoOOH has good oxidation and reduction properties and proton spread rate when the loading density is 0.617 kg/m2.The power density and energy density can be as high as 1 250 W/kg and 49.4 W·h/kg respectively when Ni(OH) 2 with CoOOH was used in high power battery with the nickel foam.
文摘In MH/Ni high power battery production, a large percent of batteries were found with an open circuit voltage lower than 1.18 V after formation, open circuit voltage of another large percent of batteries could be even as low as1.00 ~ 1.10 V after one month sitting.In this situation, we analysed the causes of the problem, and provided some efficient solution based on many experiments.It was proved that these solutions are working very well to prevent the low open circuit voltage and being used in real production.